Electronic circuit comprising an amplifier with improved transient speed

ABSTRACT

An electronic circuit comprising an amplifier includes an output terminal (OUT) for supplying an output signal (V out ) to a load, the amplifier comprising an output transistor (N 2 , P 1 ) having a first main terminal coupled to a supply voltage terminal (V SS , V DD ) of the amplifier, a second main terminal coupled to the output terminal (OUT), and a control terminal. In order to avoid that the output transistor (N 2 , P 1 ) can enter its linear state which would cause the amplifier to act unacceptably slow for some purposes, the electronic circuit further comprises a controller adapted to prevent the output transistor (N 2 , P 1 ) to enter its linear state whereby the controller is arranged for reducing a control voltage (V cntrl ) between the control terminal and the first main terminal when an output voltage (V out ) between the second main terminal and the first main terminal is below a defined level.

BACKGROUND AND SUMMARY

The invention relates to an electronic circuit comprising an amplifier comprising an output terminal for supplying an output signal to a load, the amplifier comprising an output transistor having a first main terminal coupled to a supply voltage terminal of the amplifier, a second main terminal coupled to the output terminal, and a control terminal.

Such an electronic circuit is known from the general state of the art as shown in FIG. 1. The known circuit comprises an amplifier having an amplifying complementary (class-AB) output stage driven by a class-A amplifying stage. The output stage may be followed by a unity-voltage-gain (follower-type) output stage (not drawn). Such an amplifier is e.g. used in integrated drivers for CRT'S.

A high-side output branch includes n-type transistor N₁ in common-drain configuration and p-type transistor P₁ in common gate configuration. The gate of P₁ is coupled to the positive supply voltage by means of a bias voltage source E₁ of appropriate value. In almost every technology the speed of the p-type transistor is worse than than of the n-type transistor, among others due to the difference in carrier mobility's. In applications, where the speed is at the edge of what the technology offers, the p-type transistor is preferably used in common-gate configuration, as the bandwidth of the transfer from source signal current to drain signal current approaches the transistor's transition frequency f_(T). A low-side output transistor N₂ is biased in common-source configuration. The amplifying stage consists of differential transconductor (shown as a box g_(m) in the lower part) loaded by two current sources J₁ and J₂. The differential transconductor converts the differential input voltage V_(in+)−V_(in−) to a differential output current I_(out+)−I_(out−)=g_(m) (V_(in+)−V_(in−)), in which g_(m) is the transconductance. The bias current value of both current sources J₁ and J₂ is controlled by a common-mode control loop (not shown), which essentially controls the quiescent current in the output transistors N₁, P₁ and N₂.

The voltage gain of output transistors P₁ and N₂ can be large provided that they are biased in saturation and not in the linear region. Clamping circuits can monitor the drain-to-gate voltage and take appropriate action whenever these voltages tend to enter the linear region.

FIG. 2 shows a known clamp circuit. This type of clamp circuit is generally denoted as a “Baker” clamp. In normal operation the collector-base junction is reverse biased, diode D₁ is reversed biased and diode D₂ is forward biased. Whenever the collector voltage tends to drop to below the base voltage the diode D₁ is forward biased. The bipolar transistor N₁ then operates at near-zero collector-base voltage and the excess base drive current is bypassed via D₁. As a results the bipolar transistor N₁ is kept out of saturation. The “Baker” clamp principle can also be applied to MOS transistors.

FIG. 3 shows a generalized form of the clamp circuit according to FIG. 2. The source of transistor NN is connected to the drain of the output transistor N₂. The gate of NN is connected to an appropriate voltage level, here symbolized by E_(b1). In normal operation transistor NN is cut off. Whenever N₂'s drain voltage decreases to more than a threshold voltage below NN's gate voltage, transistor NN becomes conductive and its increasing drain current can be used in the driving circuit DRV to reduce the gate drive of output transistor N₂ to keep N₂ in saturation.

FIG. 4 shows another generalized form of the clamp circuit according to FIG. 2. The gate of transistor PP senses the drain voltage of output transistor N₂. In normal operation the transistors NN and PP are cut off. Whenever N₂'s drain voltage decreases too much (to be set by the value of E_(b1) and threshold voltages of NN and PP) the transistor pair NN/PP becomes conductive and its increasing channel current can be used in driving circuit DRV to reduce the gate drive of output transistor N₂. Contrary to the circuit principle of FIG. 3 the clamping current is not conducted by the output transistor N₂.

FIG. 5 shows an input signal attenuator, known from U.S. Pat. No. 5,304,865. It comprises a MOS transistor NN and a resistor R₃, to be used in conjunction with a comparator. The source node of the MOS transistor NN can be used to sense the drain voltage. As long as this voltage is higher than the gate voltage, the MOS transistor is in saturation and the channel is cut off. The source voltage is approximately equal to the gate voltage. If the drain voltage falls below the gate bias voltage, the MOS transistor NN is rendered conductive in the linear range and the source voltage follows the drain voltage.

For some applications it can (unintentionally) occur that the output voltage V_(out) at the output terminal OUT is so low that the transistor N₂ enters its linear operating state. This causes the amplifier to react relatively slow. A similar situation, with regard to the combined transistor pair N₁/P₁, occurs when the output voltage V_(out) becomes too high. The former situations can occur when the amplifier is for instance used as a CRT-cathode-driving amplifier. High voltages characterize it: the applied supply voltage E_(sup) and the required output voltage V_(out) swing exceed the allowable gate-source voltage of for instance the transistor N₂ (some 20V) by far. The supply voltage E_(sup) can range between 50V and 250V and the required peak-to-peak output voltage V_(out) swing ranges from 40V (monochrome monitors), via 100-150V (color television) to 200V (color projection television). These applications require a speed (bandwidth, slew rate, rise time etc.) which is at the edge of what technology offers. It therefore is of prime importance that the parasitic capacitances at the gates of N₁ and N₂ in FIG. 1 are minimized.

In order to get the highest speed as possible it is necessary to avoid the output voltage V_(out) to become too high or too low, so that the transistor N₂ and the combined transistor pair N₁/P₁ are kept in their normal state of operation. In prior art circuits this is accomplished by the application of, for instance, one of the circuits as shown in FIGS. 2-4. Further the requirements for a low power consumption dictates low bias currents.

In the “Baker” clamp of FIG. 2 the clamping diode D₁ needs to withstand a reverse-bias voltage far exceeding 10V. This implies that the shallow-p (SP) to n-epitaxial layer must be used. In a junction-isolated technology forward biasing of the SP-epi junction has the disadvantage that a parasitic substrate pnp transistor is activated: the SP region acts as emitter, the epilayer as base and the p-type substrate as collector. To reduce the pnp current gain the SP-epi junction has to be surrounded as much as possible by high-dope n-type material (buried-n and deep-n diffusions). The consequences are severe: the allowable reverse-bias voltage across the diode D₁ is reduced, and the layout size and thus parasitic capacitances are increased. For high reverse-bias voltages a series connection of more diodes might be needed, which increases layout size and parasitic capacitances even more. Thus the “Baker” clamp of FIG. 2 offers too high parasitic capacitance and cannot be applied if a high speed is important.

The generalized “Baker” clamp principles of FIG. 3 and FIG. 4 cannot be be applied, because the clamping transistors are tied to the high-voltage-swing node with their gate or their source, which is not allowed in normal IC-processes. (The transistors can be damaged).

For detecting whether the output voltage V_(out) is too low (or too high), the circuit shown in FIG. 5 can be used (in which the source voltage of the MOS-transistor NN forms an input voltage for a comparator).

It is an object of the invention to provide an electronic circuit provided with an amplifier having a high (transient) speed irrespective whether the amplifier is applied in a low, medium, or high voltage electronic system.

To this end, according to the invention, an electronic circuit is provided comprising:

an amplifier comprising an output terminal for supplying an output signal to a load, the amplifier comprising an output transistor having a first main terminal coupled to a supply voltage terminal of the amplifier, a second main terminal coupled to the output terminal, and a control terminal; and

control means for avoiding the output transistor to enter its linear state, the control means being arranged to reduce a control voltage between the control terminal and the first main terminal when an output voltage between the second main terminal and the first main terminal is below a defined level.

The invention is based on the insight that if the voltage across the output transistor becomes too low, as a consequence of which the output transistor unintentionally enters its linear operating state, this is in fact caused by a too high control voltage at the output transistor. Thus by reducing the control voltage, when the voltage across the main current path of the output transistor tends to become too low, the voltage across the said main current path will no longer decrease. (In fact a negative feedback loop is created) Thus the output transistor stays in its normal state of operation thereby avoiding the amplifier to react with reduced speed.

In an embodiment of a circuit according to the invention the control means comprises level detection means for, during operation of the electronic circuit, supplying a substantial change in voltage difference when the output voltage becomes lower than the defined level, and transconductor means for supplying a control current to the amplifier for reducing the control voltage on respond to the control current. Due to the fact that the level detection means delivers a substantial, thus not a very small, change in voltage difference it is assured that the control voltage is only adapted when needed, and not by an undesired offset-voltage, which may for instance be in the transconductor means. This makes the circuit easier to design (less sensitive to design parameters) and more reliable.

BRIEF DESCRIPTION OF THE DRAWINGS

Further advantageous embodiments of the invention are specified in dependent claims.

The invention will be described in more detail with reference to the accompanying drawing, in which:

FIG. 1 is a circuit diagram of a known amplifier;

FIG. 2 is a circuit diagram of a known clamp circuit;

FIG. 3 is a circuit diagram of a generalized form of the clamp circuit according to FIG. 2;

FIG. 4 is a circuit diagram of another generalized form of the clamp circuit according to FIG. 2;

FIG. 5 is a circuit diagram of a circuit for detecting whether a certain voltage is too low;

FIG. 6 is a circuit diagram of a first embodiment of an electronic circuit according to the invention;

FIG. 7 is a circuit diagram of a second embodiment of an electronic circuit according to the invention;

FIG. 8 is a circuit diagram of a third embodiment of an electronic circuit according to the invention;

FIG. 9 is a circuit diagram of a fourth embodiment of an electronic circuit according to the invention;

FIG. 10 is a circuit diagram of a fifth embodiment of an electronic circuit according to the invention;

FIG. 11 is a circuit diagram of a sixth embodiment of an electronic circuit according to the invention;

FIG. 12 is a circuit diagram of a seventh embodiment of an electronic circuit according to the invention;

FIG. 13 is a circuit diagram of an eighth embodiment of an electronic circuit according to the invention; and

FIG. 14 is a circuit diagram of a ninth embodiment of an electronic circuit according to the invention.

In these figures parts or elements having like functions or purposes bear the same reference symbols.

DETAILED DESCRIPTION

FIG. 6 shows schematically an amplifier having a driving circuit DRV (input stage) and an output stage. Only output transistor N₂ is shown in the output stage. In fact the amplifier can be implemented in many ways, for instance in the way as shown in FIG. 1. The circuit further comprises level detection means implemented by sensing transistor N₃ and resistor R₃, and transconductor means GM. The operation of the circuit is as follows:

The gate of N₃ is biased at an appropriate DC voltage, here symbolized by voltage E_(b1) with respect to the source of N₂. The size of transistor N₃ may be small, which minimizes the parasitic capacitive load. The source of sensing transistor N₃ is connected to the input of the transconductor GM. In normal operation of output transistor N₂ (at sufficiently high drain voltage) sensing transistor N₃ is in saturation and is cut off, and its source voltage is approximately constant and approximately equal to E_(b1). Transconductor GM is designed such that under these circumstances it is not activated, so it has a negligible output current I_(cntrl).

When N₂'s drain voltage decreases, the drain-to-source voltage of sensing transistor N₃ also decreases. As long as N₃ is in saturation, its source voltage is approximately constant, though. Finally N₃ enters the linear region and N₃'s source voltage will decrease approximately linearly with the drain voltage. This will activate the transconductor GM to produce an output current I_(cntrl). The transconductor GM output current is applied in the driving circuit DRV to reduce the gate drive V_(cntrl) for output transistor N₂ such that N₂ is kept in its saturation region. In fact this takes place in an analogue feedback loop. Sensing transistor N₃ enters its linear region essentially before the output transistor N₂ would do in the known circuit.

FIG. 7 shows an alternative implementation of a circuit according to the invention. Compared to FIG. 6 the resistor R₃ is removed and the sensing transistor N₃ is biased by a current source J_(b1). In normal operation of output transistor N₂ sensing transistor N₃ is in saturation and conducts a current of value J_(b1). Contrary to the circuit of FIG. 6 the source voltage will be lower than the gate bias voltage E_(b1). Transconductor GM is designed such that its output current I_(cntrl) is negligible in these circumstances.

Whenever N₃ enters the linear region its source voltage decreases and the transconductor GM is activated. In analogy to the circuit principle of FIG. 6, the analogue clamping feedback loop, which is formed with the driving circuit DRV, keeps output transistor N₂ in its saturation region.

FIG. 8 shows the circuit of FIG. 7 in which the transconductor GM is implemented by transconductor transistor P₄. In normal operation sensing transistor N₃ is in saturation, and bias voltage source E_(b6) is chosen such that transistor P₄ is cut off. When N₃ enters the linear region its gate-source voltage increases, which activates P₄ to convert its gate-source voltage change to an output current change.

The transconductor GM can also be implemented with a complementary pair of transistors N₄/P₄, as shown in FIG. 9. The gate of N₄ is coupled to the gate of N₃, e.g. by means of a direct connection, as shown in FIG. 9. In normal operation sensing transistor N₃ is in saturation and its gate-source voltage is smaller than the sum of threshold voltages of the complementary pair N₄ and P₄, such that N₄ and P₄ are cut off. When N₃ enters the linear region its gate-source voltage increases and finally goes beyond the sum of threshold voltages of N₄ and P₄. The complementary pair N₄/P₄ is activated and behaves as a transconductor, converting an input voltage difference to an output current change I_(cntrl).

In FIG. 6, FIG. 7, FIG. 8 and FIG. 9 the gate voltage of the sensing transistor N₃ is coupled to N₂'s source voltage by means of bias voltage source E_(b1), but it can also be coupled to the output transistor's gate voltage. In FIG. 10 the invention is applied to the high-side complementary output pair N₁/P₁ of FIG. 1. The current in N₅/P₅ can be used in the driving circuit DRV to close the feedback loop to keep output transistor P₁ in its saturation region.

The circuits and clamping principles of FIG. 8, FIG. 9 and FIG. 10 can be combined with the amplifier of FIG. 1, as shown in FIG. 11. In FIGS. 11-14 GM and GM₂ have similar functions. This is also true with respect to I_(cntrl) and I2 _(cntrl) Preferably, parasitic capacitances at the gates of N₁ and N₂ are minimized. The output currents of the transistors P₄ respectively N₅ therefore are inserted at the sources of common-gate-biased transistors. P-type transistors P₆ and P₇ serve as cascode transistors to the common-mode current sources J₁ and J₂. Their gates are biased by bias voltage source E_(b4). N-type transistor N₆ serves as cascode transistor for the differential-mode transconductor GM at the amplifier inputs, and is biased by bias voltage source E_(b5). Transistor N₅ is activated when the output voltage rises too much, and draws a current from the left amplifier branch at the source of P₆. Transistor P₄ is activated when the output voltage decreases too much, and delivers a current into the left branch at the source of N₆. Whenever either one of the transistors P₄ or N₅ is activated the common-mode control loop (which is not shown in the figures, it is however generally known that differential amplifiers having differential outputs do need such control loops) is influenced. It therefore is better to insert differential mode currents, as shown in FIG. 12.

The complementary pair N₅/P₅ is activated when the output voltage V_(out) rises too much, and draws a current I2 _(cntrl) from the left amplifier branch (at the source of P₆) and delivers it into the right branch (into the source of N₇).

The complementary pair N₄/P₄ is activated when the output voltage V_(out) decreases too much, and draws a current I_(cntrl) from the right amplifier branch (at the source of P₇) and delivers it into the left branch (into the source of N₆).

Both clamping mechanisms produce differential-mode currents counteracting the differential-mode current from the differential-mode transconductor g_(m). Thus the common-mode current is unaltered and either one of the clamping circuits does not influence the common-mode control loop.

Another example is shown in FIG. 13. NPN transistors N₈ and N₉ together with resistor R₈₉ form the input differential transconductor, biased by current sources J_(b8) and J_(b9). The drain currents of P-type MOS transistors P₄ and P₅ are inserted at the emitters of the input transistors N₈ and N₉.

Normally the amplifiers are applied in negative feedback configuration with a signal voltage attenuator from output to inverting input (not shown). The attenuator usually consists of resistors and/or capacitors. This offers the opportunity to use the inverting input for clamping purposes as well: the channel current of the transconductor N₅/P₅ (or N₄/P₄)3 need not necessarily be applied to the driving electronics in differential form. FIG. 14 shows an amplifier in which the drain of the n-type transistor N₅ is tied to the positive supply voltage and the drain of the p-type transistor P₅ is tied to the inverting input of the amplifier. Thus again, the common-mode control loop, which controls the values of current sources J₁ and J₂, is not influenced when the complementary pair N₅/P₅ is activated.

There are many more ways to feed back the channel currents of the transconductor (e.g. N₄/P₄ or N₅/P₅) into the driving electronics, and close the clamping feedback loop. The way it is done may have consequences for the stability and bandwidth of the clamping feedback loop, which in fact has to overrule the normal signal path whenever either one of the output transistors has to be clamped. For that reason it is mandatory that the clamping feedback loop has at least the same bandwidth as the normal signal path, but preferably has a higher bandwidth. In that sense the circuit of FIG. 13 is to be preferred above the circuit of FIG. 14: the clamping feedback loop encloses less transistors in FIG. 13 and thus has less poles, which in general favors stability.

In the figures most transistors are shown as field effect transistors by way of example. They can however, be replaced party or wholly by bipolar transistors. Further in FIG. 13 the input transistors N₈ and N₉ can be replaced by MOS transistors.

Further P-type and N-type transistors can be replaced by N-type and P-type transistors. 

What is claimed is:
 1. An electronic circuit, comprising: an amplifier comprising an output terminal, which supplies an output signal to a load, the amplifier including an output transistor having a first main terminal coupled to a supply voltage terminal of the amplifier, a second main terminal coupled to the output terminal (OUT), and a control terminal; and a controller, which includes a transconductor device, and which is adapted to prevent the output transistor from entering its linear state, the controller being arranged to reduce a control voltage between the control terminal and the first main terminal when an output voltage between the second main terminal and the first main terminal is below a defined level.
 2. An electronic circuit as claimed in claim 1, wherein the controller comprises a level detector, which during operation of the electronic circuit, supplies a substantial change in voltage difference when the output voltage becomes lower than the defined level, and wherein the transconductor device supplies a control current to the amplifier to reduce the control voltage in response to the control current.
 3. An electronic circuit as claimed in claim 2, wherein the level detector comprises a level detection transistor having a control terminal coupled adapted to receive a reference voltage, a first main terminal, and a second main terminal coupled to the output terminal, and a resistive path coupled between the control terminal and the first main terminal of the level detection transistor, and wherein the voltage between the control terminal and the first main terminal of the level detection transistor forms the voltage difference.
 4. An electronic circuit as claimed in claim 2, wherein the level detector comprises a level detection transistor having a control terminal coupled for receiving a reference voltage, a first main terminal, and a second main terminal coupled to the output terminal, and a current source coupled between the first main terminal of the level detection transistor and the supply Voltage terminal, wherein the voltage between the control terminal and the first main terminal of the level detection transistor forms the voltage difference.
 5. An electronic circuit as claimed in claim 2, wherein the transconductor device comprises a transconductor transistor having a first main terminal, a second main terminal, and a control terminal, and the control terminal and the first main terminal are coupled to receive a voltage between the control terminal and the first main terminal of the transconductor transistor which is dependent on the aforementioned voltage difference, and the second main terminal of the transconductor transistor delivers the control current during operation of the electronic circuit.
 6. An electronic circuit, comprising: an amplifier comprising an output terminal for supplying an output signal to a load, the amplifier comprising an output transistor having a first main terminal coupled to a supply voltage terminal of the amplifier, a second main terminal coupled to the output terminal, and a control terminal; and control means for avoiding the output transistor to enter its linear state, the control means being arranged to reduce a control voltage between the control terminal and the first main terminal when an output voltage between the second main terminal and the first main terminal is below a defined level, wherein the control means comprises level detection means for supplying, during operation of the electronic circuit, a substantial change in voltage difference when the output voltage becomes lower than the defined level, and transconductor means for supplying a control current to the amplifier for reducing the control voltage on respond to the control current. 